Tuner circuit

ABSTRACT

A tuner circuit and a method of designing a tuner circuit for removing a buffer circuit for video drive for increasing drive current capacitance added to an output terminal is provided, unlike a buffer for small-current drive installed in a tuner circuit. The method of designing a tuner circuit has a buffer installed in an integrated circuit (IC) of small-current drive in a video output terminal, and includes an RF converting portion, a tuning portion and a demodulation portion, in which a video output signal of the buffer in IC is input to an input circuit for processing a signal without an external buffer for drive, and the amount of attenuation of a signal at high frequency due to small drive current is measured to improve a frequency characteristic of a video signal in the tuner circuit in proportion to the amount of attenuation. Thus, an additional buffer for drive is not required, so that the number of devices is reduced, to thereby lower the material costs.

CLAIM OF PRIORITY

This application makes reference to, incorporates the same herein, and claims all benefits accruing under 35 U.S.C §119 from an application entitled Method Of Designing Tuner Circuit earlier filed in the Korean Industrial Property Office on 5 Sep. 1998, and there duly assigned Serial No. 98-36625 by that Office.

This continuation application makes reference to, incorporates the same herein, and claims all benefits including under 35 U.S.C. §121 from a co-pending application entitled A TUNER CIRCUIT filed in the United States Patent & Trademark Office on the 7 Sep. 1999 and there duly assigned Ser. No. 09/391,614 now U.S. Pat. No. 6,483,554.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to image signal processing and image signal circuits, and, more particularly, to tuning signal processing and tuning circuits with small output drive currents exhibiting increased drive current capacitance at an output terminal.

2. Description of the Related Art

Typically, a tuning circuit in a video tape recorder (i.e., a VCR) includes an radio frequency converter, a tuner and a demodulator. A broadcasting signal received by an antenna is output to a radio frequency amplifier and an output mode switch through a distributor. The RF converter includes the distributor, an output switch, and a modulator. The tuner includes the RF amplifier, a mixer, and a local oscillator while the demodulator includes a surface acoustic wave (i.e., a SAW) filter, a demodulator, an output buffer, and frequently, an external buffer that is often necessary to provide a current necessary to drive some external appliances that is larger than can be obtained with the output buffer included in the integrated circuit.

In the operation of a typical tuning circuit constructed as an integrated cirucit, a broadcast signal is amplified at its radio frequency, mixed with a local oscillation frequency signal of a channel predetermined by the local oscillator in order to convert the broadcast signal into an intermediate frequency. The intermediate frequency is then demodulated. The demodulated video signal is applied through the internal output buffer that provides a small drive current of between approximately 0.5˜1 milli-Amperes. A selection switch selects a video signal to apply to a video signal processor from between the video signal from the tuner circuit or a video input signal applied to an input video jack. When the tuner circuit is constructed as an integrated circuit, an externally connected circuit can be driven with a driving current of approximately 0.5˜1 milli-Amperes; this range of amplitudes is common in integrated circuits. I have noticed that if a circuit connected to the integrated tuner circuit should happen to require a driving current of 10 milli-Amperes or more however, an external buffer must be incorporated into the tuner circuit between the output buffer in order to obtain a sufficiently large driving current from the integrated circuit. I have found that absent the external buffer, the ability of the integrated tuning circuit deteriorates to the point that attenuation occurs in the high frequency signal components of the video signal, thereby markedly reduces the gain of the higher frequency characteristics of the video signal.

SUMMARY OF THE INVENTION

It is therefore, an object of the present invention to provide an improved tuning process and video image signal tuning circuit.

It is another object to provide tuning signal processing and tuning circuits able to decrease drive current capacitance at an output terminal.

It is still another object to provide a process and tuning circuit able to decrease drive current capacitance at an output terminal without resort to an external buffer circuit.

It is still yet another object to provide a process and integrated tuning circuit able to reduce attenuation of the gain of the higher frequency components of a video signal.

It is a further object to provide a tuning signal process and tuning circuit having a small output drive current, that exhibits increased drive current capacitance at an output terminal.

It is a still further object to provide a process and integrated tuning circuit using a buffer that produces a small driving current while minimizing the attenuation of the higher frequency characteristics of video signals.

These and other objects may be attained with a tuning circuit and process that uses a buffer installed within an integrated circuit (IC) providing small-current drive at a video output terminal. The tuning circuit has an RF converter portion, a tuning portion and a demodulator portion. A video output signal from the buffer in the integrated circuit is input to an input circuit for processing a signal without an external buffer, and the amount of attenuation of the gain of the higher frequency components of the video signal due to the low amplitude of the small drive current improves the frequency characteristic of a video signal in the tuner circuit in proportion to the amount of attenuation.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the present invention, and many of the attendant advantages thereof, will become readily apparent as the same becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings in which like reference symbols indicate the same or similar components, wherein:

FIG. 1 is a circuit diagram of a tuning circuit and its applied peripheral circuits;

FIG. 2 is a circuit diagram of a tuner circuit and its applied peripheral circuits constructed according to the principles of the present invention for designing a tuning circuit;

FIG. 3A is a graph illustrating that frequency characteristics of a video signal when the driving current is insufficient;

FIG. 3B is a graph showing an increase the frequency characteristics of a video signal in considering the attenuation amount according to the process for designing a tuner circuit of the present invention;

FIG. 4A is a graph showing the frequency characteristics of the video signal of FIG. 3B according to a change in the design of a surface acoustic wave filter;

FIG. 4B is a graph showing the frequency characteristics of the video signal of FIG. 3B according to the design of a sound trap (SIF TRAP); and

FIG. 5 is a circuit diagram of the sound trap of FIG. 4B.

DETAILED DESCRIPTION OF THE INVENTION

Turning now to the drawings, FIG. 1 illustrates tuner circuit 1000 with a radio frequency converter portion that uses a distributor 102, a TV/VCR switch 109, and a modulator 110. The tuning portion includes a RF amplifier 103, a mixer 104, and a local oscillator 105. The demodulation portion includes a SAW filter 106, a demodulator 107, a buffer 108, and an external buffer 111. Circuits external to tuner circuit 1000 include a tuner/jack input selection switch 112, a video signal processor 113, and an external output, e.g., television (TV) 114. When the TV/VCR switch 109 is switched to the TV mode, the broadcasting signal received from the distributor 102 is applied to TV 114 in response to a control signal CTL1, and a VCR mode, i.e., video/audio signals output from the video signal processor 113 of a VCR and an audio signal processor (not shown) of a VCR is modulated to a predetermined channel by the modulator 110, and then the modulated signal is output to the TV 114.

In the operation of the tuner circuit 1000, a broadcasting signal received by an antenna 101 is output to the RF amplifier 103 and the TV/VCR switch 109 through the distributor 102, and the broadcasting signal output from the distributor 102 is amplified by the RF amplifier 103. Then, a local oscillation frequency signal of a channel predetermined by the local oscillator 105 controlled by a control signal CTL2 and the amplified broadcasting signal are mixed in the mixer 104. Thus, the mixer 104 converts the broadcasting signal to an intermediate frequency and outputs it to the demodulation portion.

A video signal is demodulated by the demodulation portion, and then the demodulated signal is output through the buffer 108 having a small drive current of approximately 0.5˜1 mA. In the tuner/jack input selection switch 112, either a video signal output from the tuner circuit 1000 or a jack video input signal is selected by a control signal CLT3 and the selected signal is input to the video signal processor 113.

In an integrated circuit (IC) having the tuner circuit 1000, an externally connected circuit can be driven by a driving current of approximately 0.5˜1 milli-Amperes. A circuit connected to the integrated circuit having the tuner circuit requires a driving current of 10 milli-Amperes or more so that the external buffer 111 for producing a sufficient driving current must be added to the integrated circuit having the tuner circuit. If the external buffer 111 for producing the driving current is not used, the driving ability is deteriorated so that the attenuation of a high frequency signal component occurs to thereby deteriorate frequency characteristic of a video signal indicated by a dotted line of FIG. 3A.

As shown in FIG. 2, a tuner circuit 2000 constructed according to the principles of the present invention includes an RF converter portion, a tuning portion, and a demodulation portion. A broadcast signal received from an antenna 201 is applied to the tuning portion and the TV/VCR switch 209 of the RF converter portion through a distributor 202. The RF converter portion includes a distributor 202, a TV/VCR switch 209, and a modulator 210. The tuning portion includes a RF amplifier 203, a mixer 204, and a local oscillator 205. The demodulation stage includes a SAW filter 206, a demodulator 207, a buffer 208, and a video signal level adjuster 211. Circuits external to tuner circuit 2000 include a tuner/jack input selection switch 212, a video signal processor 213, and an external appliance, i.e., television (TV) 214. The video jack signal is an externally generated video signal that is applied to the VCR through the input jack mounted in the rear panel of the VCR, via switch 212.

Control signals CLT1, CLT2 and CLT3 may be generated by a system controller (not shown) of the VCR that is external to the tuner circuit 2000 in response, by way of example, to a key input by a user. CTL1 is a control signal for switching the output mode of the VCR. When, for example, a user sets the output mode of the VCR to the television mode (i.e., the TV mode), the broadcast signals received via antenna 201 are applied by switch 209 directly to television set 214. When the output mode of switch 209 is set however, to the VCR mode, either the broadcast signals that pass through the tuner of the VCR or the video signals introduced to video signal processor 213 via the input jack of switch 212 are applied via switch 209 to television set 214. Consequently, during the TV mode, audio and video signals transmitted by a broadcast studio are directly applied to television set 214 via the VCR, while during the VCR mode the signals are first converted to a specific channel and are then applied via switch 209 to television set 214.

CTL2 is a control signal for selecting one of a plurality of channels. When the user selects a broadcast channel through a either a key or a remote control input (not shown), signal CTL2 controls the oscillation frequency of the local oscillator in order to convert the video signal carried by only the selected broadcast channel into an intermediate frequency signal. CTL3 selects a video signal input to the VCR via the input jack, as an input signal for video signal processor 213, in response to a key input by a user, and in default of that key input, selects the output signal from the tuner circuit 2000 to apply to signal processor 213.

When the TV/VCR switch 209 is switched to the TV mode, the broadcasting signal received from the distributor 202 is output to the TV 214 in response to a control signal CTL1, and a VCR mode, i.e., video/audio signals output from the video signal processor 213 of a VCR and an audio signal processor (not shown) of a VCR is modulated to a predetermined channel, e.g., 3/4CH in Korea and U.S., 1,2CH in Japan and 13CH in Taiwan, by the modulator 210, and then the modulated signal is output to the TV 214.

Also, in the tuning portion, the broadcasting signal output from the distributor 202 is amplified by the RF amplifier 203. Then, a local oscillation frequency signal of a channel predetermined by the local oscillator 205 controlled by a control signal CTL2 and the amplified broadcasting signal are mixed in the mixer 204. Thus, the mixer 204 converts the broadcasting signal to an intermediate frequency and outputs it to the demodulation portion.

In the demodulation portion, band characteristics of a signal are set such that a predetermined difference of gains among a picture frequency f_(P), a color frequency f_(C) and a sound frequency f_(S) is generated by the SAW filter 206 to be frequency characteristics the same as a waveform indicated by a solid line of FIG. 4A. Then, demodulation is performed by the demodulator 207, and a frequency component of the audio signal is separated by an internal sound trap (SIF TRAP) circuit, and then the separated signal is output to the buffer 208. The buffer 208 has a small drive current of approximately 0.5˜1 mA.

The level of the demodulated video signal output from an integrated circuit of a tuner circuit, including buffer 208 driven by a small current, is adjusted by resistors R201 and R202 of the video signal level adjuster 211, and the signal having the adjusted level is applied to one input terminal of the tuner/jack input selection switch 212, and a jack video input signal is applied to the other input terminal of the tuner/jack input selection switch 212.

In the tuner/jack input selection switch 212, either a video signal output from the tuner circuit 2000 or a jack video input signal is selected by a control signal CLT3 and the selected signal is input to the video signal processor 213. Also, in the video signal processor 213, a record/reproduction signal is processed per mode, and the processed signal is output to the modulator 210 of the RF converting portion of the tuner circuit 2000 to be modulated to a channel appropriate for the country in which the tuner circuit is used, and then the modulated signal is output to the TV 214 through the TV/VCR switch 209.

A more detailed discussion of the audio signal processing block of the VCR is omitted from the description of the tuning circuit in the foregoing paragraphs. An audio signal is separated by a sound trap that may be included in demodulator 207 and filtered to ground. The audio signal applied to modulator 210 is a signal that is output after a video signal is cut off by the video trap circuit. The filter is included in the audio signal processor (not shown) and only the audio signal is filtered and processed among the signal output from SAW filter 206 of the tuning portion.

According to the present invention, the video output signal of the buffer 208 for the tuner circuit 2000 is directly applied to the tuner/jack input selection switch 212 of an input circuit for processing a signal, without an external buffer for producing drive.

Thus, when a small-current video signal is generated by the tuner circuit 2000 without an external buffer for increasing the driving current to the outside of the tuner circuit 2000 of an integrated circuit, attenuation occurs in a high frequency band of the video signal due to the capacitance component existing in a printed circuit board (PCB) pattern.

Here, a design method for solving the above-described problems without adding an external drive buffer to the tuner circuit 2000 will be described.

A device having an input impedance value, more than a predetermined value, of the tuner/jack input selection switch 212 connected to an output terminal of the tuner circuit 2000 is used. This is because the drive current is increased when the input impedance of the tuner/jack input selection switch 212 is low in view of the output terminal of the tuner circuit 2000. Thus, when the input impedance value of the tuner/jack input selection switch 212 is increased, the drive current output from the tuner circuit 2000 can be relatively reduced. When the input impedance value of the tuner/jack input selection switch 212 is at least 30 kΩ or more, the drive current does not increase.

By a second method, the printed pattern length of a printed circuit board connecting an output terminal of the buffer 208 for video drive, of the tuner circuit 2000, to an input terminal of the tuner/jack input selection switch 212, is designed to be as short as possible. This improves the problem of attenuating a high frequency component due to a capacitive component in the pattern of the printed circuit board, when the drive capacity is less. That is, the pattern length of the printed circuit board connecting the output terminal of the video buffer 208 of the tuner circuit 2000 and the input terminal of the tuner/jack input selection switch 212 thereof is shortened, to thereby reduce the capacitance to a minimum and thus reduce the amount of attenuation of the high frequency component.

The lack of the drive current may cause the attenuation of signals in the high frequency band despite a design compensatory to the above problems. Thus, to compensate the attenuation of the high frequency component, as shown by the dotted line of FIG. 3B, the gain characteristic in the high frequency band is improved in accordance with the amount of attenuation caused by the lack of drive current.

By a method for improving the characteristic of a video frequency, as shown by the dotted line of FIG. 4A, a frequency near a color frequency f_(C) is boosted up by a predetermined amount in accordance with the amount of attenuation in the high frequency band by designing of a SAW filter installed in the demodulation portion of the tuner circuit 2000 to increase the characteristic of the video signal at high frequency. Also, by another method, in designing the SIF TRAP installed in the demodulation portion of the tuner circuit 2000 shown in FIG. 5, values of a ceramic filter CF1, a resistor R1 and an inductance L1 are adjusted and thus the amount of attenuation and the sharpness (Q) are adjusted as shown by the dotted line of FIG. 4B to improve the characteristic of the video signal at high frequency.

As described above, the solution of the input impedance of a device and the length of a printed circuit board pattern, and compensation of the frequency characteristic of a video signal in the tuner circuit enable compensation of the attenuation of a signal rapidly generated from the high frequency band without the external buffer 111 for video drive, which is required by the integrated tuner circuit of FIG. 1. Thus, the frequency characteristic of a video signal can be prevented from being attenuated, using a buffer for small-current drive of an integrated circuit having a tuner circuit, to thereby reduce material cost. 

What is claimed is:
 1. A circuit module for processing a radio frequency broadcast signal, comprising: an input terminal configured to receive said radio frequency broadcast signal; a tuner circuit in operable connection with said input terminal to receive said radio frequency broadcast signal therefrom, said tuner circuit being configured to convert said received radio frequency broadcast signal into at least an intermediate frequency signal; a filter in communication with said tuner circuit to receive said intermediate frequency signal therefrom, said filter being configured to define frequency characteristics of said intermediate frequency signal to produce a frequency characteristics defined intermediate frequency signal; a demodulator in communication with said filter to receive said frequency characteristics defined intermediate frequency signal therefrom, said demodulator being configured to produce at least a video signal based on said frequency characteristics defined intermediate frequency signal; and an output terminal in communication with said demodulator to receive said video signal therefrom, said output terminal being configured to output said video signal at an output level to an input of an external circuit, said filter, to compensate an attenuation of a high frequency component, among the defined frequency characteristics of said frequency characteristics defined intermediate frequency signal, when said output terminal outputs said video signal to the input of said external circuit, boosts a gain of the high frequency component of said frequency characteristics defined intermediate frequency signal by a predetermined amount to compensate the attenuation, and wherein said output terminal outputs said video signal to the input of the external circuit without using an external buffer between said output terminal and said external circuit.
 2. The circuit module as set forth in claim 1, wherein said filter compensates the attenuation of said high frequency component of said intermediate frequency signal near a color frequency.
 3. The circuit module as set forth in claim 1, wherein said demodulator comprises a sound trap configured to filter out a portion of said frequency characteristics defined intermediate frequency signal, and comprises a plurality of passive circuit elements, a value of at least one of said plurality of passive elements being adjustable to satisfy a predetermined input level of said external circuit, without using an external buffer, to allow adjustment of the range of said portion of said frequency characteristics defined intermediate frequency signal being filtered out.
 4. The circuit module as set forth in claim 1, wherein said circuit module is constructed as a single integrated circuit.
 5. A broadcasting signal processing system comprised of a circuit module for processing a radio frequency broadcast signal, said circuit module comprising: an input terminal configured to receive said radio frequency broadcast signal; a tuner circuit in operable connection with said input terminal to receive said radio frequency broadcast signal therefrom, said tuner circuit being configured to convert said received radio frequency broadcast signal into at least an intermediate frequency signal; a filter in communication with said tuner circuit to receive said intermediate frequency signal therefrom, said filter being configured to define frequency characteristics of said intermediate frequency signal to produce a frequency characteristics defined intermediate frequency signal; a demodulator in communication with said filter to receive said frequency characteristics defined intermediate frequency signal therefrom, said demodulator being configured to produce at least a video signal based on said frequency characteristics defined intermediate frequency signal; an external circuit configured to receive said video signal from said demodulator at an input, said filter, to compensate an attenuation of a high frequency component, among the defined frequency characteristics of said frequency characteristics defined intermediate frequency signal, when said external circuit receives said video signal from said demodulator, boosts a gain of the high frequency component of said video signal by a predetermined amount to compensate the attenuation, and wherein said external circuit receives said video signal from said demodulator without using an external buffer between said demodulator and said external circuit.
 6. The broadcasting signal processing system as set forth in claim 5, wherein said input terminal, said tuner circuit, and said demodulator are as a single integrated circuit.
 7. The broadcasting signal processing system as set forth in claim 5, wherein an input impedance of said external circuit is at least 30KΩ.
 8. The broadcasting signal processing system as set forth in claim 5, wherein said filter compensates the attenuation of said high frequency component of said intermediate frequency signal near a color frequency.
 9. The broadcasting signal processing system as set forth in claim 5, wherein said demodulator comprises a sound trap configured to filter out a portion of said frequency characteristics defined intermediate frequency signal, and comprises a plurality of passive circuit elements, a value of at least one of said plurality of passive elements being adjustable to satisfy a predetermined input level of said external circuit, without using an external buffer, to allow adjustment of a range of said portion of said frequency characteristics defined intermediate frequency signal being filtered out.
 10. The broadcasting signal processing system as set forth in claim 5, wherein said external circuit selectively engages an input of said video signal processor with either an output of said demodulator or an external video signal source.
 11. The broadcast signal processing system as set forth in claim 10, wherein said jack input switch circuit has an input impedance of at least 30 kΩ in view of the output of said demodulator, when said jack input switch is engaging said input of said video signal processor with said output of said demodulator.
 12. A tuner circuit, comprising: a demodulation circuit comprising an integrated circuit and configured to demodulate an intermediate frequency signal to generate a demodulated video signal, said demodulation circuit comprising: a filter configured, to compensate an attenuation of a high frequency component, among frequency characteristics of said intermediate frequency signal, when the tuner circuit outputs the demodulated video signal, to boost a gain of the high frequency component of said intermediate frequency signal by a predetermined amount to compensate for the attenuation; said tuner circuit not having a buffer external to the integrated circuit for driving the demodulated video signal.
 13. The tuner circuit as claimed in claim 12, wherein said filter is a SAW filter configured to boost the high frequency component.
 14. The tuner circuit as claimed in claim 13, wherein the high frequency component that is boosted is a frequency near a color frequency f_(c) of the demodulated video signal.
 15. The tuner circuit as claimed in claim 13, wherein said SAW filter has band characteristics such that a predetermined difference of gains among a picture frequency fp, a color frequency fc, and a sound frequency fs of said demodulated video signal is generated to provide the boost of the high frequency component.
 16. The tuner circuit as claimed in claim 12, wherein said demodulation circuit further comprises a sound trap configured to provide further compensation to supplement the compensation by the filter.
 17. The tuner circuit as claimed in claim 16, wherein a sharpness and attenuation of said sound trap are set to provide the at least part of the compensation.
 18. The tuner circuit as claimed in claim 12, wherein said demodulation circuit further comprises: a buffer; and a video signal level adjuster; said buffer configured to provide the demodulated video signal to the video signal level adjuster, and the video signal level adjuster configured to adjust a level of the demodulated video signal to a level appropriate for inputting to a circuit external to said tuner circuit.
 19. The tuner circuit as claimed in claim 18, wherein said buffer has a driving current of approximately 0.5 to 1.0 milli-Amperes.
 20. The tuner circuit as claimed in claim 18, wherein said video signal level adjuster is a voltage divider.
 21. A system, comprising: a tuner circuit having a demodulation circuit comprising an integrated circuit and configured to demodulate an intermediate frequency signal to generate a demodulated video signal, said demodulation circuit comprising: a filter configured, to compensate an attenuation of a high frequency component, among frequency characteristics of the intermediate frequency signal, when an output terminal outputs the demodulated video signal, to boost a gain of the high frequency component of said intermediate frequency signal by a predetermined amount to compensate for the attenuation, and the output terminal that outputs the demodulated video signal; said tuner circuit not having a buffer external to the integrated circuit for driving the demodulated video signal.
 22. A system, comprising: a tuner circuit configured to generate a demodulated video signal; and an external circuit, outside of the tuner circuit, that receives the demodulated video signal from the tuner circuit without said demodulated video signal having passed through a buffer external to the integrated circuit, said external circuit having an input impedance of at least 30KΩ to compensate for a reduction in drive current of the demodulated video signal caused by absence of a buffer external to the integrated circuit.
 23. The system of claim 22, wherein said tuner circuit comprises: a demodulation circuit configured to demodulate an intermediate frequency signal in a manner that provides compensation for attenuation of a high frequency component of the intermediate frequency signal, to generate the demodulated video signal.
 24. The system of claim 23, wherein said demodulation circuit comprises a filter configured to provide at least part of the compensation for the attenuation.
 25. The system as claimed in claim 23, wherein said filter is a SAW filter configured to boost the high frequency component of the intermediate frequency signal in accordance with an amount of the attenuation.
 26. The system as claimed in claim 25, wherein the high frequency component that is boosted is a frequency near a color frequency f_(c) of the demodulated video signal.
 27. The system as claimed in claim 26, wherein said SAW filter has band characteristics such that a predetermined difference of gains among a picture frequency fp, a color frequency fc, and a sound frequency fs of said demodulated video signal is generated to provide the boost of the high frequency component.
 28. The system as claimed in claim 26, wherein said demodulation circuit comprises a sound trap configured to provide at least part of the compensation.
 29. The system as claimed in claim 28, wherein a sharpness of said sound trap is set to provide the at least part of the compensation.
 30. The system as claimed in claim 23, wherein said demodulation circuit comprises: a buffer within the integrated circuit; and a video signal level adjuster; said buffer within the integrated circuit configured to provide the demodulated video signal to the video signal level adjuster, and the video signal level adjuster configured to adjust a level of the demodulated video signal to a level appropriate for inputting to a circuit external to said tuner circuit.
 31. The system as claimed in claim 30, wherein said buffer has a driving current of approximately 0.5 to 1.0 milli-Amperes.
 32. The system as claimed in claim 30, wherein said video signal level adjuster is a voltage divider.
 33. The system as claimed in claim 22, wherein the integrated circuit further comprises an output terminal that outputs the demodulated video signal, and the system further comprises a portion of a printed circuit board, the portion comprising a pattern that electrically couples said output terminal to an input terminal of an element external to said tuner circuit. 